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EP0735240B1 - Gas turbine bucket - Google Patents

Gas turbine bucket Download PDF

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Publication number
EP0735240B1
EP0735240B1 EP96300625A EP96300625A EP0735240B1 EP 0735240 B1 EP0735240 B1 EP 0735240B1 EP 96300625 A EP96300625 A EP 96300625A EP 96300625 A EP96300625 A EP 96300625A EP 0735240 B1 EP0735240 B1 EP 0735240B1
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EP
European Patent Office
Prior art keywords
passages
radial
gas turbine
passage
bucket
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
EP96300625A
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German (de)
French (fr)
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EP0735240A1 (en
Inventor
Ariel Caesar-Prepena Jacala
Michael Adelbert Sullivan
Richard Mallory Davis
Rong-Shi Paul Chiu
Fred Staub (Nmn)
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General Electric Co
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General Electric Co
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01DNON-POSITIVE DISPLACEMENT MACHINES OR ENGINES, e.g. STEAM TURBINES
    • F01D5/00Blades; Blade-carrying members; Heating, heat-insulating, cooling or antivibration means on the blades or the members
    • F01D5/12Blades
    • F01D5/14Form or construction
    • F01D5/18Hollow blades, i.e. blades with cooling or heating channels or cavities; Heating, heat-insulating or cooling means on blades
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01DNON-POSITIVE DISPLACEMENT MACHINES OR ENGINES, e.g. STEAM TURBINES
    • F01D5/00Blades; Blade-carrying members; Heating, heat-insulating, cooling or antivibration means on the blades or the members
    • F01D5/12Blades
    • F01D5/14Form or construction
    • F01D5/18Hollow blades, i.e. blades with cooling or heating channels or cavities; Heating, heat-insulating or cooling means on blades
    • F01D5/187Convection cooling
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F05INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
    • F05DINDEXING SCHEME FOR ASPECTS RELATING TO NON-POSITIVE-DISPLACEMENT MACHINES OR ENGINES, GAS-TURBINES OR JET-PROPULSION PLANTS
    • F05D2260/00Function
    • F05D2260/20Heat transfer, e.g. cooling
    • F05D2260/221Improvement of heat transfer
    • F05D2260/2212Improvement of heat transfer by creating turbulence

Definitions

  • This invention relates to a new land based gas turbine in simple or combined cycle configuration, which permits a user to incorporate air or steam cooling of hot gas turbine parts with minimal change in components.
  • the invention may also incorporate design changes enabling certain turbine components to be used without change in both 50 and 60 Hz turbines.
  • the invention here more particularly relates to cooling steam circuits for the gas turbine buckets in the first and second stages of a four stage combined cycle gas turbine.
  • Cooling passages associated with this design technology are typically serpentine arrangements along the mean camber line of the blades.
  • the camber line is the locus of points between the low pressure and high pressure sides of the airfoil.
  • Adjacent radial passages are connected alternately at the top and bottom by 180 degree return U-bends to form either a single continuous passage, or independent serpentine passages, with the cooling air exiting into the gas path by one or a combination of the following schemes (a) leading edge holes, (b) hole exits along the trailing edge, (c) hole exits on the high pressure side and low pressure sides of the blade airfoil, and (d) tip cap holes.
  • Each radial passage typically cools both the high pressure and low pressure sides of the blade airfoil.
  • the specific geometry of each radial cooling passage is designed to balance the conflicting demands for low pressure drop and high heat transfer rate.
  • Schemes used in the state of the art to enhance heat transfer rate include raised rib turbulence promoters (also known as trip strips or turbulators), passage crossover impingement, the use of impingement inserts, and the use of banks or rows of pins. These schemes increase the local turbulence in the flow and thus raise the rate of heat transfer.
  • the effectiveness of open circuit air cooling is further improved by the coverage of the blade airfoil by an insulating film of air bled through openings in the airfoil surface.
  • compressor bleed flow is inherently parasitic.
  • turbine component cooling is achieved at the expense of gas turbine thermodynamic efficiency. Cooling schemes involving high pressure and high density fluids, such as steam, on the other hand, have not yet been employed for blade cooling or reduced to practice in commercially available gas turbines.
  • US-A-5165852 shows a gas turbine bucket in accordance with the preamble to claim 1.
  • the object of this invention is to provide a turbine blade design which can be used to operate under gas turbine conditions with very high external combustion gas temperatures (about 1315K 2400° F) and high internal pressure coolant supply conditions (41.6 - 68.4 bar) (600-1000 psi) typical of extraction steam available from the steam turbine cycle of a combined cycle steam and gas turbine power plant.
  • Commonly owned co-pending application EP 0 735 243 entitled “Removable Inner Turbine Shell With Bucket Tip Clearance Control” discloses a removable inner shell which permits easy access and conversion of stage 1 and 2 stator and rotor components from air to steam cooling.
  • Commonly owned co-pending application EP 0 735 238 entitled “Closed Or Open Circuit Cooling Of Turbine Rotor Components” discloses the manner in which the cooling steam is fed to the stage 1 and 2 buckets.
  • This invention relates to the stage 1 and 2 turbine blades per se, and seeks to maximize the thermodynamic efficiency of the gas turbine cycle by using steam as the turbine blade coolant instead of air bled from the gas turbine compressor for the first and second stages of the gas turbine, i.e., the stages where cooling is most critical.
  • the design of closed circuit steam cooled blades and associated coolant passages is determined in accordance with the following additional criteria;
  • the high gas inlet temperatures required to maximize gas turbine thermodynamic efficiency are sufficient to melt metals used in gas turbine blade construction.
  • the blades used in the first few stages are cooled to prevent melting, stress rupture, excessive creep and oxidation.
  • the cooling must be judiciously applied to prevent premature cracking due to low cycle fatigue.
  • the continuing increases in gas turbine inlet temperature, and the use of combined cycles to maximize the thermal efficiency of power plants bring into consideration the use of steam as a coolant for gas turbine hot gas path components.
  • steam as a coolant for gas turbine blade cooling
  • One advantage is that of potentially superior heat transfer.
  • steam has an up to 70% advantage in heat transfer coefficient in turbulent duct flow by virtue of its higher specific heat (other considerations being equal).
  • the more important advantage is higher gas turbine thermal efficiency. Since the compressor bleed air is no longer needed for cooling the first and second stages, it can be put to good use as increased flow in the gas path for conversion into shaft work for higher turbine output for the same fuel heat input.
  • problems associated with steam as a coolant however, which stem from the requirement of maintaining a closed circuit and the already mentioned high supply pressures typical of reheat extraction in a steam power plant.
  • closed circuit cooling the coolant is supplied and removed from the shank of the blade, and a single serpentine circuit is provided within the blade, including multiple radial outflow and radial inflow passages.
  • Closed circuit cooling (as opposed to open circuit cooling typically used when air is the cooling medium) is preferred because: (a) otherwise, large amounts of make-up water would be required in the steam turbine cycle (assuming a combined cycle configuration), and (b) it would be more deleterious for thermodynamic efficiency to bleed and mix steam into the gas path (as compared to air) because of steam's greater capability to quench and reduce the work capability of the hot combustion gas because of steam's higher heat capacity.
  • High coolant pressures are required because reheat steam is usually extracted at high pressure to optimize steam turbine cycle thermodynamic efficiency. Thin airfoil walls, usually required for cooling purposes, may not be sufficient for the pressure difference between the internal coolant, steam, and the gas path, resulting in excessive mechanical stresses. Steam pressures may be in excess of 3-5 times typical compressor bleed air (e.g. 41.6-68.4 bar 600-1000 psi steam versus 13.8 bar 200 psi air). A new design is thus required which can operate under high heat fluxes and high supply pressures simultaneously.
  • the Buoyancy Number, B o obtained from the ratio of the buoyancy to inertia force of the forced convection flow is defined by the Grashof number divided by the Reynolds number squared (Gr/Re 2 ).
  • the cooling fluid in the internal blade cooling passages is more prone to develop secondary flows from Coriolis and centrifugal buoyancy forces which (a) affect the predictability of heat transfer and (b) impair the heat transfer by uneven heat pickup or potential flow reversal.
  • one side of the airfoil is ahead of the other in the direction of rotation. The side of the airfoil which is ahead is the leading side and the one which is behind is the trailing side.
  • the rotor itself dictates that the temperature of the coolant exiting the turbine be no more than about 1088 K (1050° F) due to the properties of Inconel, for example, of which the rotor is formed.
  • the steam coolant entering the turbine should be about 638 K - 677 K (690°-760° F) (given a pressure of about 41.6-68.4 bar 600-1000 psi).
  • the temperature will be somewhat higher (about 810 K 1000° F) and the pressure somewhat lower (about 48.2 700 psi).
  • combustion gases are likely to enter the first stage at about (2400° F) 1588 K and the maximum metal temperature needs to be reduced to below about 1255 K (1800° F).
  • second stage temperatures are likely to be 1366 K (2000° F) and 1650°.
  • the mass flow of coolant and coolant passage areas can be determined.
  • the passages can be designed to accommodate (i.e., minimize) Coriolis and buoyancy effects.
  • novel features of the turbine blade designs in accordance with this invention are thus found in the blade cooling passages and the exclusive use of high pressure steam as the blade cooling fluid in the gas turbine first and second stages.
  • the third stage remains air cooled and the fourth stage remains uncooled in conventional fashion.
  • radial passages in the turbine blade are configured in a single serpentine, closed circuit, with steam entering along the trailing edge of the blade and exiting along the leading edge of the blade.
  • the number of radial inflow and outflow passages may be any number depending upon the demands of the above design criteria.
  • the radial passages are connected alternately by 180 degree return U-bends and each passage includes 45 degree angle raised rib turbulence enhancers.
  • the radial outflow passages are made deliberately smaller than the radial inflow passages, with the exception of the radial inflow (or exit) passage along the leading edge of the airfoil. The reasons for this exception are explained further herein.
  • the smaller radial outflow passages counteract the tendency for any radial secondary flow recirculation resulting from centrifugal buoyancy forces acting on the cooling fluid. This adverse tendency is counteracted by making the bulk flow velocity as large as possible in radial outflow within the confines of producibility and pressure drop.
  • the radial outflow passages are designed with aspect ratios (length to width cross-section dimensions for the passages), such that buoyancy parameters lead to maximized heat transfer rate on the leading side of the passage as substantiated by test results.
  • the target regime of operation in radial outflow is a Buoyancy Number of less than 0.15 or greater than 0.8 for passages with an aspect ratio of 3.3 to 1.
  • the above embodiment also features the use of turbulence enhancing raised ridges or trip strips to enhance the heat transfer rate. These features have the additional benefit of reducing the adverse effects of buoyancy and Coriolis forces as the local turbulence breaks up secondary flow tendencies. This effect also has been documented (for air) in the literature (see, for example, Wagner, J.H., Steuber, G., Johnson, B., and Yeh, F., "Heat Transfer in Rotating Serpentine Passages with Trips Skewed to the Flow"). Rows of pins may also be used in trailing edge passages for both mechanical strength and heat transfer.
  • Cooling the tip portion of a closed circuit cooled blade presents additional problems.
  • Typical high technology open circuit air cooled designs bleed coolant near the tip to reduce the heat flux around the tip periphery of the airfoil. The reduced heat fluxes reduce the temperature gradient through the wall and the associated thermal stresses.
  • closed circuit cooling the mechanism for solving the problem is solely by internal convective cooling.
  • Tip cooling is addressed by incorporating raised ribs on the underside of the blade tip cap. These ribs increase the local turbulence and thus enhance the rate of heat transfer.
  • Another feature is the incorporation of bleed holes at the juncture where the rib meets the wall and the tip cap.
  • the aforementioned feature provides relief from high thermal stresses by unconstraining the corner region from the relatively cold rib.
  • the situation is further improved by chamfering or radiusing the external corner at the juncture of the airfoil wall and the tip cap. This reduces the effective wall thickness and reduces the temperature gradient across the wall of the airfoil around the periphery of the tip cap.
  • the flow is reversed, i.e. the flow moves radially outward through the leading edge passage and then follows a similar serpentine arrangement, in reverse, exiting through the trailing edge passage.
  • the present invention may be defined as comprising a gas turbine bucket having a shank portion, a radial tip portion and an airfoil having leading and trailing edges and pressure and suction sides, and an internal fluid cooling circuit, the improvement comprising the internal fluid cooling circuit having a serpentine configuration including plural radial outflow passages and plural radial inflow passages, the radial outflow passages shaped to have aspect ratios of about 3.3 to 1 and Buoyancy Numbers of ⁇ 0.15 or > 0.80.
  • the invention may be defined as comprising a gas turbine bucket having a shank portion, a radial tip portion and an airfoil extending between the shank portion and the radial tip portion, the airfoil having leading and trailing edges and pressure and suction sides, and an internal fluid cooling circuit, the improvement comprising the internal fluid cooling circuit having a serpentine configuration including plural radial outflow passages and plural radial inflow passages, the radial outflow passages having, on average, smaller cross-sectional areas than the radial inflow passages.
  • the invention aims at achieving the following advantages:
  • FIG. 1 is a schematic diagram for a simple-cycle, single-shaft heavy duty gas turbine 10.
  • the gas turbine may be considered as comprising a multi-stage axial flow compressor 12 having a rotor shaft 14. Air entering the inlet of the compressor at 16 is compressed by the axial flow compressor 12, and then is discharged to a combustor 18 where fuel such as natural gas is burned to provide high energy combustion gases which drive a turbine 20. In the turbine 20, the energy of the hot gases is converted into work, some of which is used to drive compressor 12 through shaft 14, with the remainder being available for useful work to drive a load such as a generator 22 by means of rotor shaft 24 (an extension of the shaft 14) for producing electricity.
  • a typical simple-cycle gas turbine will convert 30 to 35% of the fuel input into shaft output. All but one to two percent of the remainder is in the form of exhaust heat which exits turbine 20 at 26.
  • Figure 2 represents the combined cycle in its simplest form in which the energy in the exhaust gases exiting turbine 20 at 26 is converted into additional useful work.
  • the exhaust gases enter a heat recovery steam generator (HRSG) 28 in which water is converted to steam in the manner of a boiler.
  • HRSG heat recovery steam generator
  • the steam thus produced drives a steam turbine 30 in which additional work is extracted to drive through shaft 32 an additional load such as a second generator 34 which, in turn, produces additional electric power.
  • turbines 20 and 30 drive a common generator. Combined cycles producing only electrical power are in the 50% to 60% thermal efficiency range using the more advanced gas turbines.
  • steam used to cool the gas turbine buckets in the first and second stages may be extracted from a combined cycle system in the manner described in commonly owned application S.N. 08/161,070 filed December 3, 1993.
  • This invention does not relate to the combined cycle per se, but rather, to the configuration of internal steam cooling passages in the first and second stage gas turbine buckets, consistent with the discussions above.
  • FIG. 3 illustrates in greater detail the area of the gas turbine which is the focus of this invention.
  • Air from the compressor 12' is discharged to the several combustors located circumferentially about the gas turbine rotor 14' in the usual fashion, one such combustor shown at 36.
  • the resultant gases are used to drive the gas turbine 20' which includes in the instant example, four successive stages, represented by four wheels 38, 40, 42 and 44 mounted on the gas turbine rotor for rotation therewith, and each including buckets or blades represented respectively, by numerals 46, 48, 50 and 52 which are arranged alternately between fixed stators represented by vanes 54, 56, 58 and 60.
  • This invention relates specifically to steam cooling of the first and second stage buckets, represented by blades 46, 48, and the minimization of secondary Coriolis and centrifugal buoyancy forces or effects in the internal blade cooling passages.
  • a typical passage 2 is shown in a blade 4 having a leading (or suction) side 6 and a trailing (or pressure) side 8.
  • the Coriolis induced secondary flow (assume rotation in the direction of arrow A) transports cooler, higher momentum fluid from the core to the trailing side 8, whereby the radial velocity, the temperature gradient and hence the convective effects are enhanced. Centrifugal buoyancy increases the radial velocity of the coolant near the trailing side 8, further enhancing the convective effect.
  • the leading side 6 the situation is just the reverse. Due to the Coriolis induced secondary flow, the fluid exchanges heat with the trailing side 8 and side walls before reaching the leading side 6.
  • the fluid adjacent to the leading side 6 is warmer and the temperature gradient in the fluid is lower, weakening the convection effect.
  • the Coriolis induced flow leads to a lower radial velocity adjacent to the leading side 6, weakening the convection effect further. Buoyancy effects become stronger at high density ratios such that flow reversal can occur adjacent to the leading side 6 of the passage 2.
  • One of the objectives of this invention is to account for the presence of these secondary flows in order to mitigate the adverse effects by appropriate design of the internal cooling passages in the buckets, and particularly the radial outflow passages where the secondary flow effects are more severe.
  • the external appearance of the gas turbine first stage bucket 46 in accordance with this invention is shown.
  • the external appearance of the blade or bucket 46 is typical compared to other gas turbine blades, in that it consists of an airfoil 62 attached to a platform 64 which seals the shank 66 of the bucket from the hot gases in the flow path via a radial seal pin 68.
  • the shank 66 is covered by two integral plates or skirts 70 (forward and aft) to seal the shank section from the wheelspace cavities via axial seal pins (not shown).
  • the shank is attached to the rotor disks by a dovetail attachment 72.
  • Angel wing seals 74, 76 provide sealing of the wheelspace cavities.
  • a novel feature of the invention is the dovetail appurtenance 78 under the bottom shank of the dovetail which supplies and removes cooling steam from the bucket via axially arranged passages 80, 82 shown in phantom, which communicate with axially oriented rotor passages (not shown).
  • FIG. 6 illustrates in simplified form, the internal cooling passages in the first stage bucket 46.
  • Steam entering the bucket via passage 80 flows through a single, closed serpentine circuit having a total of eight radially extending passages 84, 86, 88, 90, 92, 94, 96 and 98 connected alternatively by 180° return U-bends.
  • Flow continues through the shank via the radial inflow passage 98 which communicates with the axially arranged exit conduit 82.
  • Outflow passage 84 communicates with inlet passage 80 via passage 100, while inflow passage 98 communicates with exit passage 82 via radial passage 102.
  • the total number of radial passages may vary in accordance with the specific design criteria.
  • Figure 7 is a schematic planar representation of the bucket shown in Figure 4, and illustrates the incorporation of integral, raised ribs 104 generally arranged at 45° angles in the radial inflow and outflow passages, after the first radial outflow passage, which serve as turbulence enhancers. These ribs also appear at different angles in the 180° U-bends connecting the various inflow and outflow passages.
  • turbulator ribs 104 are provided along both the leading (or low pressure) side and the trailing (or pressure) side of the blade or bucket 46.
  • Pins 106 (Figs. 6, 7) provided in the radial outflow passage 84 adjacent the trailing edge improve both mechanical strength and heat transfer characteristics. These pins may have different cross-sectional shapes as evident from a comparison of Figures 6 and 7.
  • Figure 8A represents a transverse section through the root of the blade 46 and the flow arrows indicate radial inflow and outflow in the various passages 84, 86, 88, 90, 92, 94, 96 and 98.
  • the cooling steam flows into the bucket initially via passage 84 adjacent the trailing edge 108 and exits via passage 98 adjacent the leading edge 109.
  • the radial outflow passages 84, 88, 92 and 96 are made smaller than radial inflow passages 86, 90, 94 with the exception of the radial inflow passage 98 adjacent the leading edge 109 for reasons explained below.
  • the adverse effect of Coriolis and buoyancy forces are more benign in radial inflow passages, and these passages are therefore kept relatively large.
  • the leading edge passage 98 requires a high heat transfer coefficient. This is forced by reducing the flow area to raise the bulk flow velocity, which in turn raises the heat transfer coefficient which is proportional to mass flow divided by the perimeter raised to the 0.8 power.
  • the smaller cross section of passage 98 results in a smaller perimeter, thus raising the heat transfer coefficient.
  • the generally smaller radial outflow passages 84, 88, 92 and 96 counteract the tendency for any radial secondary flow recirculation resulting from Coriolis and centrifugal buoyancy forces acting on the fluid in radial outflow. This adverse tendency is counteracted by making the bulk flow velocity as large as possible in radial outflow within the confines of producibility and pressure drop.
  • the radial outflow passages 84, 88. 92 and 96 are thus designed such that buoyancy parameters lead to enhanced heat transfer rate on the leading side of the outflow passages.
  • Figure 8B illustrates the same bucket 46, but with the cross-section taken at the pitchline of the blade, halfway between the hub or root and the tip.
  • Figure 8C shows the same blade at the radially outer tip. From these views, the relative changes in passage geometry from root to tip may be appreciated.
  • the passages were also provided with turbulators 104.
  • the cross-sectional area ratio between the larger radial intlow passages (with the exception of the smaller radial inflow passage along the leading edge) and the smaller radial outflow passages at the pitchline, on average, should be about 1 1 ⁇ 2 to 1.
  • the aspect ratios may be on the order of 1 to 1 or 2 to 1, while the cross-sectional area ratios may remain substantially as for the first stage buckets.
  • turbulence enhancing ribs or turbulators 104 also tend to reduce the adverse effects of buoyancy and Coriolis forces as the local turbulence breaks up secondary flow tendencies.
  • Figures 9 and 10A-10C illustrate a second stage bucket in views which generally correspond to the first stage bucket shown in Figures 6 and 8A-8C.
  • the stage two bucket 110 has six cooling passages, as opposed to the eight passages in the first stage bucket, reflecting the reduced cooling requirements in the second stage.
  • radial outflow passages 112, 116 and 120 alternate with radial inflow passages 114, 118 and 122 in a single, closed serpentine circuit.
  • the first radial outflow passage 112 is connected to axial supply conduit 124 via passage 126 while the last radial inflow passage 122 is connected to axial return conduit 128 via passage 130.
  • Pins 132 appear in the last radial inflow passage 122, and it will be appreciated from Figs. 10A-10C that raised ribs 134 are provided as in the stage one buckets.
  • the Buoyancy Number, aspect ratio and cross-sectional area ratios are as stated above.
  • the bucket tips are cooled by providing raised ribs on the underside of the tip cap as shown in Figures 11-13.
  • the tip cap 136 of a bucket 138 is formed with integral ribs 140 on the underside of the cap in a U-bend between radial outflow passage 142 and radial inflow passage 144.
  • Turning vanes 146 may be located in outflow passage 142 to direct flow into the turnaround cavity corner 148 which is a typical location of stagnant flow and insufficient cooling.
  • integral ribs 240 of squared off configuration are provided on the underside of the tip cap 236, in further combination with turning vanes 246 and 246' in both outflow and inflow passages 242, 244, respectively.
  • raised rib turbulators or trip strips 149 are provided in the 180° U-bend region and on the underside of the tip cap 336 in combination with rounded ribs 340 on the underside of the tip cap. These features also increase local turbulence but, at least with regard to the turning vanes 146 and turbulators 149, may not provide any heat transfer enhancement.
  • bleed holes 150 may be provided where the passageway divider rib 152 meets the blade walls 154, 156 and the tip cap 158. This feature tends to provide relief from high thermal stresses by unconstraining the corner region from the rib. Additional benefits may be gained by chamfering or radiusing the external corners of the blade at 160. This reduces the effective wall thickness and reduces the temperature gradient across the wall of the airfoil around the periphery of the tip cap 158.
  • FIGS 15-18 alternative design configurations for first stage turbine buckets are shown which are intended to enhance heat transfer in the generally triangularly shaped (in cross section) trailing edge cooling passage.
  • the flow adjacent the trailing edge is laminar due to the constriction of the core flow between the boundary layers.
  • the second stage bucket does not experience the same trailing edge phenomenon, so long as the trailing edge wedge angle is below about 12°.
  • parallel flow passages 162, 164 are provided near the trailing edge 166 of the blade 168, fed from the same entry passage 170.
  • One passage 164 is intended to enhance heat transfer at the trailing edge through an arrangement of opposed baffles 172, 174.
  • the other branch or passage 162 is intended to enable a high through flow by providing a bypass to minimize overall pressure drop. Both passages meet near the blade tip to continue into the serpentine circuit, and specifically into a radial inflow passage 176.
  • the trailing edge passage 164 with its arrangement of baffles 172, 174, forces turbulence through the trailing edge region via vortices caused by U-return bends (similar to the return bends at the blade tip) between adjacent baffles projecting alternately from opposite sides of the passage 164.
  • Passage 164 will have 10-20% of the total flow from entry passage 170 because of the high flow resistance from the head losses in all of the U-bends. In the exemplary embodiment, there are about 10 such U-bends (eleven baffles 172, 174 are shown).
  • the turbulence enhancement will bring the effective heat transfer coefficient to about 11356 kJ/m 2 (1000 BTU/ft. 2 ).
  • the number of serpentine inflow and outflow passages can be reduced in this embodiment to six, in order to keep overall flow in excess of 30 pps. It is important to keep total flow rate at about 30 pps or greater, in order to keep exit temperatures below 838 K (1050° F), and to maximize leading edge heat transfer.
  • the flow split along the trailing edge 166 of the blade 168, and the overall pressure drop, will be controlled by several variables including (a) the relative size of the bypass radial outflow passages; (b) the degree of overlap of the baffles 172, 174; (c) the number of baffles; (d) the angle of inclination of the baffles, and particularly the radially innermost baffle; and (d) inlet and/or exit constrictions in the trailing edge flows.
  • FIG 16 A variation of the above trailing edge passage configuration is illustrated in Figure 16 where two parallel bypass passages 178 and 180 extend parallel to the trailing edge passage 182.
  • the radial outflow passages 178, 180 and 182 split from a common entry or supply passage (not shown) similar to passage 170 in the Figure 15 embodiment. This arrangement increases the percent of coolant bypassing the trailing edge passage 182.
  • a radial outflow passage arrangement involves parallel passages 184, 186 along the trailing edge 188 of the blade 190. Flow from radial outflow passage 186 splits at the blade tip, with some of the flow moving into the narrow diameter inflow trailing edge passage 184, and some of the flow moving into an interior radial inflow passage 192 in the closed serpentine circuit. The edge passage 184 exits into a passage 194 leaving the blade.
  • Figure 18 illustrates a variation of Figure 15 where vanes 196 are utilized in the trailing edge passage 164' in place of baffles 172, 174 to promote turbulence.
  • the flow distribution is controlled by variables discussed above in connection with Figure 15.
  • chevron turbulators 198 as illustrated in Figures 15-18 may be preferred in particular circumstances over the 45° turbulators 104 in the earlier described embodiments, in light of higher heat transfer enhancement with this type of turbulence promotor for the same pressure drop. Some 45° angle turbulators may be retained, however, if particular passages are too small to accommodate a chevron-shaped turbulator. It will be appreciated that various configurations of 45° and chevron-shaped turbulators may be included. It has also been determined that the first one third of the passage length, as measured from the flow entry point, may be left unturbulated in order to minimize pressure drop. In addition, inlet entry turbulence provides the necessary enhancement so that turbulators are not required in this part of the passage length.

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Description

  • This invention relates to a new land based gas turbine in simple or combined cycle configuration, which permits a user to incorporate air or steam cooling of hot gas turbine parts with minimal change in components. The invention may also incorporate design changes enabling certain turbine components to be used without change in both 50 and 60 Hz turbines. The invention here more particularly relates to cooling steam circuits for the gas turbine buckets in the first and second stages of a four stage combined cycle gas turbine.
  • Gas turbine blades have historically used compressor bleed air as the cooling medium to obtain acceptable service temperatures. Cooling passages associated with this design technology are typically serpentine arrangements along the mean camber line of the blades. The camber line is the locus of points between the low pressure and high pressure sides of the airfoil. Adjacent radial passages are connected alternately at the top and bottom by 180 degree return U-bends to form either a single continuous passage, or independent serpentine passages, with the cooling air exiting into the gas path by one or a combination of the following schemes (a) leading edge holes, (b) hole exits along the trailing edge, (c) hole exits on the high pressure side and low pressure sides of the blade airfoil, and (d) tip cap holes.
  • Each radial passage typically cools both the high pressure and low pressure sides of the blade airfoil. The specific geometry of each radial cooling passage is designed to balance the conflicting demands for low pressure drop and high heat transfer rate. Schemes used in the state of the art to enhance heat transfer rate include raised rib turbulence promoters (also known as trip strips or turbulators), passage crossover impingement, the use of impingement inserts, and the use of banks or rows of pins. These schemes increase the local turbulence in the flow and thus raise the rate of heat transfer. The effectiveness of open circuit air cooling is further improved by the coverage of the blade airfoil by an insulating film of air bled through openings in the airfoil surface. The disadvantage of using compressor bleed flow, however, is that it is inherently parasitic. In other words, turbine component cooling is achieved at the expense of gas turbine thermodynamic efficiency. Cooling schemes involving high pressure and high density fluids, such as steam, on the other hand, have not yet been employed for blade cooling or reduced to practice in commercially available gas turbines.
  • US-A-5165852 shows a gas turbine bucket in accordance with the preamble to claim 1.
  • The object of this invention is to provide a turbine blade design which can be used to operate under gas turbine conditions with very high external combustion gas temperatures (about 1315K 2400° F) and high internal pressure coolant supply conditions (41.6 - 68.4 bar) (600-1000 psi) typical of extraction steam available from the steam turbine cycle of a combined cycle steam and gas turbine power plant. Commonly owned co-pending application EP 0 735 243 entitled "Removable Inner Turbine Shell With Bucket Tip Clearance Control" discloses a removable inner shell which permits easy access and conversion of stage 1 and 2 stator and rotor components from air to steam cooling. Commonly owned co-pending application EP 0 735 238 entitled "Closed Or Open Circuit Cooling Of Turbine Rotor Components" discloses the manner in which the cooling steam is fed to the stage 1 and 2 buckets.
  • This invention relates to the stage 1 and 2 turbine blades per se, and seeks to maximize the thermodynamic efficiency of the gas turbine cycle by using steam as the turbine blade coolant instead of air bled from the gas turbine compressor for the first and second stages of the gas turbine, i.e., the stages where cooling is most critical. In reaching the desired goal, the design of closed circuit steam cooled blades and associated coolant passages is determined in accordance with the following additional criteria;
  • 1) minimum coolant pressure loss;
  • 2) predictable and adequate heat transfer;
  • 3) metal temperature consistent with part life objectives;
  • 4) minimization of secondary flow effects; and
  • 5) ease of manufacture.
  • By way of additional background, the high gas inlet temperatures required to maximize gas turbine thermodynamic efficiency are sufficient to melt metals used in gas turbine blade construction. The blades used in the first few stages are cooled to prevent melting, stress rupture, excessive creep and oxidation. The cooling must be judiciously applied to prevent premature cracking due to low cycle fatigue. The continuing increases in gas turbine inlet temperature, and the use of combined cycles to maximize the thermal efficiency of power plants bring into consideration the use of steam as a coolant for gas turbine hot gas path components.
  • The use of steam as a coolant for gas turbine blade cooling can provide several advantages. One advantage is that of potentially superior heat transfer. For example, when comparing typical high pressure extraction steam to compressor bleed air, steam has an up to 70% advantage in heat transfer coefficient in turbulent duct flow by virtue of its higher specific heat (other considerations being equal). The more important advantage is higher gas turbine thermal efficiency. Since the compressor bleed air is no longer needed for cooling the first and second stages, it can be put to good use as increased flow in the gas path for conversion into shaft work for higher turbine output for the same fuel heat input. There are problems associated with steam as a coolant, however, which stem from the requirement of maintaining a closed circuit and the already mentioned high supply pressures typical of reheat extraction in a steam power plant. In closed circuit cooling, the coolant is supplied and removed from the shank of the blade, and a single serpentine circuit is provided within the blade, including multiple radial outflow and radial inflow passages.
  • Closed circuit cooling (as opposed to open circuit cooling typically used when air is the cooling medium) is preferred because: (a) otherwise, large amounts of make-up water would be required in the steam turbine cycle (assuming a combined cycle configuration), and (b) it would be more deleterious for thermodynamic efficiency to bleed and mix steam into the gas path (as compared to air) because of steam's greater capability to quench and reduce the work capability of the hot combustion gas because of steam's higher heat capacity.
  • High coolant pressures are required because reheat steam is usually extracted at high pressure to optimize steam turbine cycle thermodynamic efficiency. Thin airfoil walls, usually required for cooling purposes, may not be sufficient for the pressure difference between the internal coolant, steam, and the gas path, resulting in excessive mechanical stresses. Steam pressures may be in excess of 3-5 times typical compressor bleed air (e.g. 41.6-68.4 bar 600-1000 psi steam versus 13.8 bar 200 psi air). A new design is thus required which can operate under high heat fluxes and high supply pressures simultaneously.
  • Other problems arise from the high pressure and high density steam used as a coolant. For example, the density of steam at 68.4 bar (1000 psia) is 3 times the density of air at 13.8 bar (200 psia) (at the same temperature, for example, 699 K (800°F)). At the same time, the heat capacity of steam is roughly twice that of air under the same conditions. This means that lesser amounts of steam mass flow are required for the equivalent convection cooling. The Buoyancy Number, Bo, obtained from the ratio of the buoyancy to inertia force of the forced convection flow is defined by the Grashof number divided by the Reynolds number squared (Gr/Re2). With air cooled blades, undesirable buoyancy effects are typically small, Bo < < 1. The buoyancy effects are greater with steam, however, and as the buoyancy factor Bo approaches unity, the undesirable effects become even more significant. The internal coolant passages for a steam cooled system must therefore be designed to account for Coriolis and buoyancy effects, also known as secondary flow effects, explained in greater detail below.
  • More specifically, at the higher densities and low flow rates (lower flow velocities for a given passage cross sectional area) of steam, the cooling fluid in the internal blade cooling passages is more prone to develop secondary flows from Coriolis and centrifugal buoyancy forces which (a) affect the predictability of heat transfer and (b) impair the heat transfer by uneven heat pickup or potential flow reversal. As the blade rotates about the shaft axis, one side of the airfoil is ahead of the other in the direction of rotation. The side of the airfoil which is ahead is the leading side and the one which is behind is the trailing side. It is shown in the literature (for example, see Prakash and Zerkle, "Prediction of Turbulent Flow and Heat Transfer in a Radially Rotating Square Duct," Paper HTD-Vol. 188), that, when air is the coolant, flow tends to move from the high pressure region near the leading side to the low pressure region near the trailing side in the plane of the coolant passage cross section. The effects are more severe when steam is the coolant.
  • It has also been determined that Coriolis and buoyancy forces or effects are most significant in the radial outflow passages of the serpentine cooling circuit, particularly in the region from the pitchline (halfway between the hub and the tip of the bucket) to the tip of the bucket or blade. Accordingly, the focus in this invention is on the bucket radial outflow passage design. Any such design requires prior knowledge of the flow conditions which would set up these adverse flow recirculations at which point, passage size, and shape can be used to minimize any adverse effects.
  • The parameters which must be taken into account in any such design process include:
  • a) mass flow rate of the combustion gases entering the gas turbine;
  • b) heat transfer coefficients of coolants;
  • c) surface area to be cooled;
  • d) temperature of combustion gases at bucket leading edge;
  • e) temperature of the bucket; and
  • f) heat flux.
  • In addition, certain material limitations dictate certain aspects of the design. For example, in one embodiment, the rotor itself dictates that the temperature of the coolant exiting the turbine be no more than about 1088 K (1050° F) due to the properties of Inconel, for example, of which the rotor is formed. This, in turn, dictates that the steam coolant entering the turbine should be about 638 K - 677 K (690°-760° F) (given a pressure of about 41.6-68.4 bar 600-1000 psi). By the time the steam coolant reaches the first and second stages of the turbine, the temperature will be somewhat higher (about 810 K 1000° F) and the pressure somewhat lower (about 48.2 700 psi).
  • In accordance with the anticipated operating parameters of this new gas turbine, combustion gases are likely to enter the first stage at about (2400° F) 1588 K and the maximum metal temperature needs to be reduced to below about 1255 K (1800° F). Corresponding second stage temperatures are likely to be 1366 K (2000° F) and 1650°.
  • With these conditions set, the mass flow of coolant and coolant passage areas can be determined. At the same time, given a mass flow and inlet temperature (TIN) for the coolant, the passages can be designed to accommodate (i.e., minimize) Coriolis and buoyancy effects.
  • The novel features of the turbine blade designs in accordance with this invention are thus found in the blade cooling passages and the exclusive use of high pressure steam as the blade cooling fluid in the gas turbine first and second stages. The third stage remains air cooled and the fourth stage remains uncooled in conventional fashion.
  • In a first exemplary embodiment, radial passages in the turbine blade are configured in a single serpentine, closed circuit, with steam entering along the trailing edge of the blade and exiting along the leading edge of the blade. The number of radial inflow and outflow passages may be any number depending upon the demands of the above design criteria. The radial passages are connected alternately by 180 degree return U-bends and each passage includes 45 degree angle raised rib turbulence enhancers.
  • In a transverse cross section through the pitchline of the airfoil, the radial outflow passages are made deliberately smaller than the radial inflow passages, with the exception of the radial inflow (or exit) passage along the leading edge of the airfoil. The reasons for this exception are explained further herein.
  • The smaller radial outflow passages counteract the tendency for any radial secondary flow recirculation resulting from centrifugal buoyancy forces acting on the cooling fluid. This adverse tendency is counteracted by making the bulk flow velocity as large as possible in radial outflow within the confines of producibility and pressure drop. The radial outflow passages are designed with aspect ratios (length to width cross-section dimensions for the passages), such that buoyancy parameters lead to maximized heat transfer rate on the leading side of the passage as substantiated by test results. The target regime of operation in radial outflow is a Buoyancy Number of less than 0.15 or greater than 0.8 for passages with an aspect ratio of 3.3 to 1. As already noted above, it is known that the adverse effect of Coriolis and buoyancy forces are more benign to radial inflow passages when air is used as the coolant. (See, for example, Wagner, J.H., Johnson, B., and Kopper, F., "Heat Transfer in Rotating Serpentine Passages with Smooth Walls," ASME Paper 90-GT-331, 1990.) We have confirmed that this is also the case for steam. As such, the radial inflow passages are kept relatively large within the confines of desired heat transfer coefficients and pressure drop constraints.
  • The above embodiment also features the use of turbulence enhancing raised ridges or trip strips to enhance the heat transfer rate. These features have the additional benefit of reducing the adverse effects of buoyancy and Coriolis forces as the local turbulence breaks up secondary flow tendencies. This effect also has been documented (for air) in the literature (see, for example, Wagner, J.H., Steuber, G., Johnson, B., and Yeh, F., "Heat Transfer in Rotating Serpentine Passages with Trips Skewed to the Flow"). Rows of pins may also be used in trailing edge passages for both mechanical strength and heat transfer.
  • Cooling the tip portion of a closed circuit cooled blade presents additional problems. Typical high technology open circuit air cooled designs bleed coolant near the tip to reduce the heat flux around the tip periphery of the airfoil. The reduced heat fluxes reduce the temperature gradient through the wall and the associated thermal stresses. In closed circuit cooling, the mechanism for solving the problem is solely by internal convective cooling.
  • Tip cooling is addressed by incorporating raised ribs on the underside of the blade tip cap. These ribs increase the local turbulence and thus enhance the rate of heat transfer.
  • Another feature is the incorporation of bleed holes at the juncture where the rib meets the wall and the tip cap. The aforementioned feature provides relief from high thermal stresses by unconstraining the corner region from the relatively cold rib. The situation is further improved by chamfering or radiusing the external corner at the juncture of the airfoil wall and the tip cap. This reduces the effective wall thickness and reduces the temperature gradient across the wall of the airfoil around the periphery of the tip cap.
  • In a variation of the above design, the flow is reversed, i.e. the flow moves radially outward through the leading edge passage and then follows a similar serpentine arrangement, in reverse, exiting through the trailing edge passage.
  • It has also been found that incorporation of the disclosed embodiments in actual blade design may require coupling with a thermal barrier coating on the blade outer surface to keep blade temperatures within acceptable limits.
  • In one aspect, therefore, the present invention may be defined as comprising a gas turbine bucket having a shank portion, a radial tip portion and an airfoil having leading and trailing edges and pressure and suction sides, and an internal fluid cooling circuit, the improvement comprising the internal fluid cooling circuit having a serpentine configuration including plural radial outflow passages and plural radial inflow passages, the radial outflow passages shaped to have aspect ratios of about 3.3 to 1 and Buoyancy Numbers of < 0.15 or > 0.80.
  • In another aspect, the invention may be defined as comprising a gas turbine bucket having a shank portion, a radial tip portion and an airfoil extending between the shank portion and the radial tip portion, the airfoil having leading and trailing edges and pressure and suction sides, and an internal fluid cooling circuit, the improvement comprising the internal fluid cooling circuit having a serpentine configuration including plural radial outflow passages and plural radial inflow passages, the radial outflow passages having, on average, smaller cross-sectional areas than the radial inflow passages.
  • The invention aims at achieving the following advantages:
  • 1. Closed circuit steam cooling using high pressure steam achieves bulk cooling effectiveness greater than that of open circuit air cooling.
  • 2. Closed circuit steam cooling of turbine blades increases gas turbine thermodynamic efficiency by eliminating parasitic compressor bleed flow for turbine blade cooling.
  • 3. The adverse effects of the rotational Coriolis and buoyancy forces and possible flow reversal in outward flow have been reduced through proper passage design for the flow rate of coolant, particularly in the radial outflow passages.
  • 4. The adverse effects of the rotational Coriolis and buoyancy forces and possible flow reversal have been further reduced by the use of turbulator ribs or trip strips.
  • 5. A more even distribution of heat transfer rate around the periphery of the coolant cavity has been maximized by the passage design.
  • 6. Regions of flow stagnation in the tip turnaround have been eliminated by the use of turning vanes and/or raised rib turbulators.
  • 7. Tip cooling has been enhanced by use of raised rib turbulators on the underside of the cap.
  • 8. Thermal stresses at the outer periphery of the tip cap are relieved by bleed holes which are placed at the juncture of the rib, the airfoil wall and the tip cap.
  • 9. The passages have been designed to maximize heat transfer and sustain high internal pressures.
  • Advantages and benefits beyond those discussed above will become apparent from the detailed description which follows.
  • BRIEF DESCRIPTION OF THE DRAWINGS
  • FIGURE 1 is a schematic diagram of a simple cycle, single shaft, heavy duty gas turbine;
  • FIGURE 2 is a schematic diagram of a combined cycle gas turbine/steam turbine system in its simplest form;
  • FIGURE 3 is a partial cross section of a portion of the gas turbine in accordance with the invention;
  • FIGURE 4 is a section through a typical turbine blade with internal cooling passages;
  • FIGURE 4A is an enlarged, planar representation of a flow passage from Figure 4, and illustrating secondary flow effects;
  • FIGURE 5 is a perspective view of a first stage turbine blade in accordance with this invention;
  • FIGURE 6 is a perspective view similar to Figure 5 but broken away to show internal cooling passages;
  • FIGURE 7 is a planar side view of the blade shown in Figure 5, with internal passages shown in phantom:
  • FIGURES 8A-C are sections of a first stage gas turbine blade in accordance with the invention, the sections taken at the hub, pitchline and tip of the blade, respectively;
  • FIGURE 9 is a perspective view, partly in section, of a second stage turbine blade in accordance with the invention;
  • FIGURES 10A-C are sections of a second stage blade, taken at the hub, pitchline, and tip, respectively;
  • FIGURE 11 is a partial, enlarged section of a blade tip, illustrating internal tip cooling in accordance with the invention;
  • FIGURE 12 is a view similar to Figure 11 but illustrating an alternative blade tip cooling arrangement;
  • FIGURE 13 is a view similar to Figure 11 but illustrating another blade tip cooling arrangement in accordance with the invention;
  • FIGURE 14A is a section through a blade illustrating bleed holes in the passages dividers in accordance with the invention;
  • FIGURE 14B is a partial section taken along the line 14B-14B in Figure 14A;
  • FIGURE 15 is a partial section of a first stage turbine blade in accordance with another exemplary embodiment of the invention:
  • FIGURE 16 is a partial section of a first stage turbine blade in accordance with still another exemplary embodiment of the invention;
  • FIGURE 17 is a partial section of a first stage turbine blade in accordance with still another exemplary embodiment of the invention; and
  • FIGURE 18 shows a variation of Figure 15.
  • Figure 1 is a schematic diagram for a simple-cycle, single-shaft heavy duty gas turbine 10. The gas turbine may be considered as comprising a multi-stage axial flow compressor 12 having a rotor shaft 14. Air entering the inlet of the compressor at 16 is compressed by the axial flow compressor 12, and then is discharged to a combustor 18 where fuel such as natural gas is burned to provide high energy combustion gases which drive a turbine 20. In the turbine 20, the energy of the hot gases is converted into work, some of which is used to drive compressor 12 through shaft 14, with the remainder being available for useful work to drive a load such as a generator 22 by means of rotor shaft 24 (an extension of the shaft 14) for producing electricity. A typical simple-cycle gas turbine will convert 30 to 35% of the fuel input into shaft output. All but one to two percent of the remainder is in the form of exhaust heat which exits turbine 20 at 26.
  • Figure 2 represents the combined cycle in its simplest form in which the energy in the exhaust gases exiting turbine 20 at 26 is converted into additional useful work. The exhaust gases enter a heat recovery steam generator (HRSG) 28 in which water is converted to steam in the manner of a boiler. The steam thus produced drives a steam turbine 30 in which additional work is extracted to drive through shaft 32 an additional load such as a second generator 34 which, in turn, produces additional electric power. In some configurations, turbines 20 and 30 drive a common generator. Combined cycles producing only electrical power are in the 50% to 60% thermal efficiency range using the more advanced gas turbines.
  • In the present invention, steam used to cool the gas turbine buckets in the first and second stages may be extracted from a combined cycle system in the manner described in commonly owned application S.N. 08/161,070 filed December 3, 1993. This invention does not relate to the combined cycle per se, but rather, to the configuration of internal steam cooling passages in the first and second stage gas turbine buckets, consistent with the discussions above.
  • Figure 3 illustrates in greater detail the area of the gas turbine which is the focus of this invention. Air from the compressor 12' is discharged to the several combustors located circumferentially about the gas turbine rotor 14' in the usual fashion, one such combustor shown at 36. Following combustion, the resultant gases are used to drive the gas turbine 20' which includes in the instant example, four successive stages, represented by four wheels 38, 40, 42 and 44 mounted on the gas turbine rotor for rotation therewith, and each including buckets or blades represented respectively, by numerals 46, 48, 50 and 52 which are arranged alternately between fixed stators represented by vanes 54, 56, 58 and 60. This invention relates specifically to steam cooling of the first and second stage buckets, represented by blades 46, 48, and the minimization of secondary Coriolis and centrifugal buoyancy forces or effects in the internal blade cooling passages.
  • Referring to Figures 4 and 4A, a typical passage 2 is shown in a blade 4 having a leading (or suction) side 6 and a trailing (or pressure) side 8. The Coriolis induced secondary flow (assume rotation in the direction of arrow A) transports cooler, higher momentum fluid from the core to the trailing side 8, whereby the radial velocity, the temperature gradient and hence the convective effects are enhanced. Centrifugal buoyancy increases the radial velocity of the coolant near the trailing side 8, further enhancing the convective effect. For the leading side 6, the situation is just the reverse. Due to the Coriolis induced secondary flow, the fluid exchanges heat with the trailing side 8 and side walls before reaching the leading side 6. The fluid adjacent to the leading side 6 is warmer and the temperature gradient in the fluid is lower, weakening the convection effect. For the same reason, the Coriolis induced flow leads to a lower radial velocity adjacent to the leading side 6, weakening the convection effect further. Buoyancy effects become stronger at high density ratios such that flow reversal can occur adjacent to the leading side 6 of the passage 2. One of the objectives of this invention is to account for the presence of these secondary flows in order to mitigate the adverse effects by appropriate design of the internal cooling passages in the buckets, and particularly the radial outflow passages where the secondary flow effects are more severe.
  • Referring now to Figure 5, the external appearance of the gas turbine first stage bucket 46 in accordance with this invention is shown. The external appearance of the blade or bucket 46 is typical compared to other gas turbine blades, in that it consists of an airfoil 62 attached to a platform 64 which seals the shank 66 of the bucket from the hot gases in the flow path via a radial seal pin 68. The shank 66 is covered by two integral plates or skirts 70 (forward and aft) to seal the shank section from the wheelspace cavities via axial seal pins (not shown). The shank is attached to the rotor disks by a dovetail attachment 72. Angel wing seals 74, 76 provide sealing of the wheelspace cavities. A novel feature of the invention is the dovetail appurtenance 78 under the bottom shank of the dovetail which supplies and removes cooling steam from the bucket via axially arranged passages 80, 82 shown in phantom, which communicate with axially oriented rotor passages (not shown).
  • Figure 6 illustrates in simplified form, the internal cooling passages in the first stage bucket 46. Steam entering the bucket via passage 80 flows through a single, closed serpentine circuit having a total of eight radially extending passages 84, 86, 88, 90, 92, 94, 96 and 98 connected alternatively by 180° return U-bends. Flow continues through the shank via the radial inflow passage 98 which communicates with the axially arranged exit conduit 82. Outflow passage 84 communicates with inlet passage 80 via passage 100, while inflow passage 98 communicates with exit passage 82 via radial passage 102. The total number of radial passages may vary in accordance with the specific design criteria.
  • Figure 7 is a schematic planar representation of the bucket shown in Figure 4, and illustrates the incorporation of integral, raised ribs 104 generally arranged at 45° angles in the radial inflow and outflow passages, after the first radial outflow passage, which serve as turbulence enhancers. These ribs also appear at different angles in the 180° U-bends connecting the various inflow and outflow passages. Referring to Figures 8A-8C, it can be seen that turbulator ribs 104 are provided along both the leading (or low pressure) side and the trailing (or pressure) side of the blade or bucket 46.
  • Pins 106 (Figs. 6, 7) provided in the radial outflow passage 84 adjacent the trailing edge improve both mechanical strength and heat transfer characteristics. These pins may have different cross-sectional shapes as evident from a comparison of Figures 6 and 7.
  • Figure 8A represents a transverse section through the root of the blade 46 and the flow arrows indicate radial inflow and outflow in the various passages 84, 86, 88, 90, 92, 94, 96 and 98. Note again that the cooling steam flows into the bucket initially via passage 84 adjacent the trailing edge 108 and exits via passage 98 adjacent the leading edge 109. The radial outflow passages 84, 88, 92 and 96 are made smaller than radial inflow passages 86, 90, 94 with the exception of the radial inflow passage 98 adjacent the leading edge 109 for reasons explained below. As already noted, the adverse effect of Coriolis and buoyancy forces are more benign in radial inflow passages, and these passages are therefore kept relatively large.
  • The leading edge passage 98 requires a high heat transfer coefficient. This is forced by reducing the flow area to raise the bulk flow velocity, which in turn raises the heat transfer coefficient which is proportional to mass flow divided by the perimeter raised to the 0.8 power. The smaller cross section of passage 98 results in a smaller perimeter, thus raising the heat transfer coefficient.
  • The generally smaller radial outflow passages 84, 88, 92 and 96 counteract the tendency for any radial secondary flow recirculation resulting from Coriolis and centrifugal buoyancy forces acting on the fluid in radial outflow. This adverse tendency is counteracted by making the bulk flow velocity as large as possible in radial outflow within the confines of producibility and pressure drop. The radial outflow passages 84, 88. 92 and 96 are thus designed such that buoyancy parameters lead to enhanced heat transfer rate on the leading side of the outflow passages.
  • Figure 8B illustrates the same bucket 46, but with the cross-section taken at the pitchline of the blade, halfway between the hub or root and the tip. Figure 8C shows the same blade at the radially outer tip. From these views, the relative changes in passage geometry from root to tip may be appreciated.
  • With a judicious selection of aspect ratios (the ratio of length dimension "L" to the width dimension "W" as shown in Figure 8B) and cross-sectional area ratios in the radial outflow passages, as explained below, it is possible to achieve, for a given aspect ratio, a buoyancy factor (for steam) of < 1, and even as low as 0.15 in the radial outflow passages 84, 88, 92 and 96 where secondary flow effects are critical. In this way, the unwanted secondary flow effects (buoyancy and Coriolis) can be minimized particularly in the radial outflow passages, while at the same time maximizing local heat transfer. In this regard, it has been determined that it is desirable to achieve a heat transfer enhancement factor ( actual heat transfer / heat transfer in a smooth tube) as high as possible. For example, when the radial outflow passages are shaped to have an aspect ratio of from about 2 to 1 to about 3.3 to 1, it has been determined that, with regard to heat transfer enhancement and Buoyancy Number (Bo), an enhancement factor of 2 is achievable with a corresponding Bo of 0.15. Between Bo's of 0.15 and 0.80, it has been discovered that the enhancement factor drops below 2. As a result, radial outflow passages should be designed to have Bo's of less than 0.15 or greater than 0.80 when the aspect ratio is about 3.3 to 1.
  • For purposes of the above analysis, the passages were also provided with turbulators 104.
  • It is expected that a similar undesirable range of Buoyancy numbers will be identified for other aspect ratios, but this has not yet been confirmed.
  • It will be appreciated that these aspect ratios will change somewhat along the length of the blade, from hub to tip due to the changing curvature and twist of the blade. At the same time, the cross-sectional area ratio between the larger radial intlow passages (with the exception of the smaller radial inflow passage along the leading edge) and the smaller radial outflow passages at the pitchline, on average, should be about 1 ½ to 1.
  • Since secondary flow effects are typically more significant in first stage buckets, it follows that aspect ratio effects are also more significant in the first stage buckets. Thus, in the second stage buckets, the aspect ratios may be on the order of 1 to 1 or 2 to 1, while the cross-sectional area ratios may remain substantially as for the first stage buckets. Once having determined the configuration of the radial outflow passages, the radial inflow passages can be configured consistent with requirements relating to heat transfer coefficients and pressure drop constraints.
  • It should be noted here that the turbulence enhancing ribs or turbulators 104 also tend to reduce the adverse effects of buoyancy and Coriolis forces as the local turbulence breaks up secondary flow tendencies.
  • Figures 9 and 10A-10C illustrate a second stage bucket in views which generally correspond to the first stage bucket shown in Figures 6 and 8A-8C. The stage two bucket 110 has six cooling passages, as opposed to the eight passages in the first stage bucket, reflecting the reduced cooling requirements in the second stage. Thus, radial outflow passages 112, 116 and 120 alternate with radial inflow passages 114, 118 and 122 in a single, closed serpentine circuit. The first radial outflow passage 112 is connected to axial supply conduit 124 via passage 126 while the last radial inflow passage 122 is connected to axial return conduit 128 via passage 130. Pins 132 appear in the last radial inflow passage 122, and it will be appreciated from Figs. 10A-10C that raised ribs 134 are provided as in the stage one buckets. The Buoyancy Number, aspect ratio and cross-sectional area ratios are as stated above.
  • An alternative design variation is also illustrated in Figure 9.
    Specifically, the steam coolant flow path is reversed, i.e., steam enters the bucket 110 and flows radially outwardly in leading edge passage 112 and exits the bucket via trailing edge passage 122. This arrangement may be advantageous in some circumstances.
  • In both first and second turbine stages, the bucket tips are cooled by providing raised ribs on the underside of the tip cap as shown in Figures 11-13. In Figure 11, for example, the tip cap 136 of a bucket 138 is formed with integral ribs 140 on the underside of the cap in a U-bend between radial outflow passage 142 and radial inflow passage 144. Turning vanes 146 may be located in outflow passage 142 to direct flow into the turnaround cavity corner 148 which is a typical location of stagnant flow and insufficient cooling. In Figure 12, integral ribs 240 of squared off configuration are provided on the underside of the tip cap 236, in further combination with turning vanes 246 and 246' in both outflow and inflow passages 242, 244, respectively. In Figure 13, raised rib turbulators or trip strips 149 are provided in the 180° U-bend region and on the underside of the tip cap 336 in combination with rounded ribs 340 on the underside of the tip cap. These features also increase local turbulence but, at least with regard to the turning vanes 146 and turbulators 149, may not provide any heat transfer enhancement.
  • In Figures 14A and 14B, it can be seen that bleed holes 150 may be provided where the passageway divider rib 152 meets the blade walls 154, 156 and the tip cap 158. This feature tends to provide relief from high thermal stresses by unconstraining the corner region from the rib. Additional benefits may be gained by chamfering or radiusing the external corners of the blade at 160. This reduces the effective wall thickness and reduces the temperature gradient across the wall of the airfoil around the periphery of the tip cap 158.
  • Turning to Figures 15-18, alternative design configurations for first stage turbine buckets are shown which are intended to enhance heat transfer in the generally triangularly shaped (in cross section) trailing edge cooling passage. The flow adjacent the trailing edge is laminar due to the constriction of the core flow between the boundary layers. It should be noted that the second stage bucket does not experience the same trailing edge phenomenon, so long as the trailing edge wedge angle is below about 12°.
  • With specific reference now to Figure 15, parallel flow passages 162, 164 are provided near the trailing edge 166 of the blade 168, fed from the same entry passage 170. One passage 164 is intended to enhance heat transfer at the trailing edge through an arrangement of opposed baffles 172, 174. The other branch or passage 162 is intended to enable a high through flow by providing a bypass to minimize overall pressure drop. Both passages meet near the blade tip to continue into the serpentine circuit, and specifically into a radial inflow passage 176. In this embodiment, the trailing edge passage 164 with its arrangement of baffles 172, 174, forces turbulence through the trailing edge region via vortices caused by U-return bends (similar to the return bends at the blade tip) between adjacent baffles projecting alternately from opposite sides of the passage 164. Passage 164 will have 10-20% of the total flow from entry passage 170 because of the high flow resistance from the head losses in all of the U-bends. In the exemplary embodiment, there are about 10 such U-bends (eleven baffles 172, 174 are shown).
  • Tests indicate that enhancement factors of 1.5 to 2 are possible at the U-bends at the blade tip. With ten baffles in the passage 164, an exit hydraulic diameter prior to the U-bends of about 8.8 mm (0.35 inches) will result in a smooth wall heat transfer coefficient of about 5678 kJ/m2 (500 BTU/ft.2). The turbulence enhancement will bring the effective heat transfer coefficient to about 11356 kJ/m2 (1000 BTU/ft.2). In addition, the number of serpentine inflow and outflow passages hydraulic diameter prior to the U-bends of about 8.8 mm (0.35 inches) will result in a smooth wall heat transfer coefficient of about 5678 kJ/m2 (500 BTU/ft.2). The turbulence enhancement will bring the effective heat transfer coefficient to about 11356 kJ/m2 (1000 BTU/ft.2). In addition, the number of serpentine inflow and outflow passages can be reduced in this embodiment to six, in order to keep overall flow in excess of 30 pps. It is important to keep total flow rate at about 30 pps or greater, in order to keep exit temperatures below 838 K (1050° F), and to maximize leading edge heat transfer.
  • The flow split along the trailing edge 166 of the blade 168, and the overall pressure drop, will be controlled by several variables including (a) the relative size of the bypass radial outflow passages; (b) the degree of overlap of the baffles 172, 174; (c) the number of baffles; (d) the angle of inclination of the baffles, and particularly the radially innermost baffle; and (d) inlet and/or exit constrictions in the trailing edge flows.
  • A variation of the above trailing edge passage configuration is illustrated in Figure 16 where two parallel bypass passages 178 and 180 extend parallel to the trailing edge passage 182. Here again, the radial outflow passages 178, 180 and 182 split from a common entry or supply passage (not shown) similar to passage 170 in the Figure 15 embodiment. This arrangement increases the percent of coolant bypassing the trailing edge passage 182.
  • Turning to Figure 17, a radial outflow passage arrangement involves parallel passages 184, 186 along the trailing edge 188 of the blade 190. Flow from radial outflow passage 186 splits at the blade tip, with some of the flow moving into the narrow diameter inflow trailing edge passage 184, and some of the flow moving into an interior radial inflow passage 192 in the closed serpentine circuit. The edge passage 184 exits into a passage 194 leaving the blade.
  • Figure 18 illustrates a variation of Figure 15 where vanes 196 are utilized in the trailing edge passage 164' in place of baffles 172, 174 to promote turbulence. Here again, the flow distribution is controlled by variables discussed above in connection with Figure 15.
  • It should also be noted that chevron turbulators 198 as illustrated in Figures 15-18, may be preferred in particular circumstances over the 45° turbulators 104 in the earlier described embodiments, in light of higher heat transfer enhancement with this type of turbulence promotor for the same pressure drop. Some 45° angle turbulators may be retained, however, if particular passages are too small to accommodate a chevron-shaped turbulator. It will be appreciated that various configurations of 45° and chevron-shaped turbulators may be included. It has also been determined that the first one third of the passage length, as measured from the flow entry point, may be left unturbulated in order to minimize pressure drop. In addition, inlet entry turbulence provides the necessary enhancement so that turbulators are not required in this part of the passage length.

Claims (6)

  1. A gas turbine bucket (46) having a shank portion (66), a tip portion (136) and an airfoil (62) having leading and trailing edges (109,108) and pressure and suction sides (8,6), and an internal fluid cooling circuit, said internal cooling circuit having a serpentine configuration including plural radial outflow passages (84, 88, 92, 96) and radial inflow passages (86, 90, 94, 98) characterized by the average of the cross sectional areas of said zodial outflow passages being smaller than the average of the cross sectional areas of said zodial inflow passages.
  2. The gas turbine bucket of claim 1 wherein a radial inflow (98) passage adjacent the leading edge of the bucket has a smaller cross sectional area than the radial outflow passages.
  3. The gas turbine bucket of claim 1 or 2, wherein said radial outflow passages each have an aspect ratio (L/W) in the plane of the pitch line of the bucket half way between the hub or root of the bucket and the tip from about 2 to 1 to about 3.3 to 1.
  4. The gas turbine bucket of claim 3 wherein a ratio of the cross sectional area of the radial inflow passages to the cross sectional area of the radial outflow passage averages about 1.5 to 1.
  5. The gas turbine bucket of any preceding claim, wherein the radial outflow passages are configured to give Buoyancy numbers in said radial outflow passages of <0.15 or >0.80:
  6. The gas turbine bucket of any preceding claim, wherein the radial inflow and radial outflow passages are configured for a steam coolant temperature of 538°C (1000°F) at a pressure of about 48267 kilopascals (&00 psi.).
EP96300625A 1995-03-31 1996-01-30 Gas turbine bucket Expired - Lifetime EP0735240B1 (en)

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US08/414,700 US5536143A (en) 1995-03-31 1995-03-31 Closed circuit steam cooled bucket
US414700 2003-04-16

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Cited By (2)

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US9726024B2 (en) 2011-12-29 2017-08-08 General Electric Company Airfoil cooling circuit

Families Citing this family (124)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2961065B2 (en) * 1995-03-17 1999-10-12 三菱重工業株式会社 Gas turbine blade
US5839267A (en) * 1995-03-31 1998-11-24 General Electric Co. Cycle for steam cooled gas turbines
DE19634237A1 (en) * 1996-08-23 1998-02-26 Asea Brown Boveri Coolable shovel
DE19634238A1 (en) * 1996-08-23 1998-02-26 Asea Brown Boveri Coolable shovel
US5842829A (en) * 1996-09-26 1998-12-01 General Electric Co. Cooling circuits for trailing edge cavities in airfoils
DE19654115A1 (en) * 1996-12-23 1998-06-25 Asea Brown Boveri Device for cooling a wall on both sides
US5829245A (en) * 1996-12-31 1998-11-03 Westinghouse Electric Corporation Cooling system for gas turbine vane
US5797726A (en) * 1997-01-03 1998-08-25 General Electric Company Turbulator configuration for cooling passages or rotor blade in a gas turbine engine
JP3238344B2 (en) * 1997-02-20 2001-12-10 三菱重工業株式会社 Gas turbine vane
JP3442959B2 (en) * 1997-02-21 2003-09-02 三菱重工業株式会社 Gas turbine blade cooling medium passage
JPH10252412A (en) * 1997-03-12 1998-09-22 Mitsubishi Heavy Ind Ltd Gas turbine sealing device
US5819525A (en) * 1997-03-14 1998-10-13 Westinghouse Electric Corporation Cooling supply manifold assembly for cooling combustion turbine components
JPH10266803A (en) * 1997-03-25 1998-10-06 Mitsubishi Heavy Ind Ltd Gas turbine cooling moving blade
JPH10280904A (en) * 1997-04-01 1998-10-20 Mitsubishi Heavy Ind Ltd Cooled rotor blade for gas turbine
US5924843A (en) * 1997-05-21 1999-07-20 General Electric Company Turbine blade cooling
WO1998055735A1 (en) 1997-06-06 1998-12-10 Mitsubishi Heavy Industries, Ltd. Gas turbine blade
EP0890710B1 (en) * 1997-07-07 2004-05-12 Mitsubishi Heavy Industries, Ltd. Gas turbine moving blade arrangement comprising a steam cooling system
DE59709275D1 (en) * 1997-07-14 2003-03-13 Alstom Switzerland Ltd Cooling system for the trailing edge area of a hollow gas turbine blade
JPH11241602A (en) * 1998-02-26 1999-09-07 Toshiba Corp Gas turbine blade
CA2231988C (en) * 1998-03-12 2002-05-28 Mitsubishi Heavy Industries, Ltd. Gas turbine blade
US6474947B1 (en) * 1998-03-13 2002-11-05 Mitsubishi Heavy Industries, Ltd. Film cooling hole construction in gas turbine moving-vanes
US6059529A (en) * 1998-03-16 2000-05-09 Siemens Westinghouse Power Corporation Turbine blade assembly with cooling air handling device
CA2280751C (en) * 1998-07-07 2002-12-31 Mitsubishi Heavy Industries, Ltd. Gas turbine blade
US6019572A (en) * 1998-08-06 2000-02-01 Siemens Westinghouse Power Corporation Gas turbine row #1 steam cooled vane
US6099252A (en) * 1998-11-16 2000-08-08 General Electric Company Axial serpentine cooled airfoil
EP1022435B1 (en) * 1999-01-25 2009-06-03 General Electric Company Internal cooling circuit for a gas turbine bucket
US6234753B1 (en) * 1999-05-24 2001-05-22 General Electric Company Turbine airfoil with internal cooling
US6224336B1 (en) * 1999-06-09 2001-05-01 General Electric Company Triple tip-rib airfoil
US6582584B2 (en) 1999-08-16 2003-06-24 General Electric Company Method for enhancing heat transfer inside a turbulated cooling passage
EP1087102B1 (en) * 1999-09-24 2010-09-29 General Electric Company Gas turbine bucket with impingement cooled platform
US6406260B1 (en) * 1999-10-22 2002-06-18 Pratt & Whitney Canada Corp. Heat transfer promotion structure for internally convectively cooled airfoils
EP1101901A1 (en) * 1999-11-16 2001-05-23 Siemens Aktiengesellschaft Turbine blade and method of manufacture for the same
US6331098B1 (en) * 1999-12-18 2001-12-18 General Electric Company Coriolis turbulator blade
US6422817B1 (en) 2000-01-13 2002-07-23 General Electric Company Cooling circuit for and method of cooling a gas turbine bucket
US6390774B1 (en) 2000-02-02 2002-05-21 General Electric Company Gas turbine bucket cooling circuit and related process
US6506013B1 (en) 2000-04-28 2003-01-14 General Electric Company Film cooling for a closed loop cooled airfoil
US6435814B1 (en) 2000-05-16 2002-08-20 General Electric Company Film cooling air pocket in a closed loop cooled airfoil
US6468031B1 (en) 2000-05-16 2002-10-22 General Electric Company Nozzle cavity impingement/area reduction insert
US6481972B2 (en) 2000-12-22 2002-11-19 General Electric Company Turbine bucket natural frequency tuning rib
US6579005B2 (en) 2000-12-28 2003-06-17 General Electric Company Utilization of pyrometer data to detect oxidation
US6382914B1 (en) 2001-02-23 2002-05-07 General Electric Company Cooling medium transfer passageways in radial cooled turbine blades
US6511293B2 (en) * 2001-05-29 2003-01-28 Siemens Westinghouse Power Corporation Closed loop steam cooled airfoil
US6485262B1 (en) 2001-07-06 2002-11-26 General Electric Company Methods and apparatus for extending gas turbine engine airfoils useful life
US6769877B2 (en) 2002-10-18 2004-08-03 General Electric Company Undercut leading edge for compressor blades and related method
US6902376B2 (en) * 2002-12-26 2005-06-07 General Electric Company Compressor blade with dovetail slotted to reduce stress on the airfoil leading edge
US7121803B2 (en) * 2002-12-26 2006-10-17 General Electric Company Compressor blade with dovetail slotted to reduce stress on the airfoil leading edge
FR2857406B1 (en) * 2003-07-10 2005-09-30 Snecma Moteurs COOLING THE TURBINE RINGS
US6939102B2 (en) * 2003-09-25 2005-09-06 Siemens Westinghouse Power Corporation Flow guide component with enhanced cooling
US7021892B2 (en) * 2003-11-19 2006-04-04 Massachusetts Institute Of Technology Method for assembling gas turbine engine components
US6984102B2 (en) * 2003-11-19 2006-01-10 General Electric Company Hot gas path component with mesh and turbulated cooling
US7008179B2 (en) * 2003-12-16 2006-03-07 General Electric Co. Turbine blade frequency tuned pin bank
US6994525B2 (en) * 2004-01-26 2006-02-07 United Technologies Corporation Hollow fan blade for gas turbine engine
US7104759B2 (en) * 2004-04-01 2006-09-12 General Electric Company Compressor blade platform extension and methods of retrofitting blades of different blade angles
US7217092B2 (en) * 2004-04-14 2007-05-15 General Electric Company Method and apparatus for reducing turbine blade temperatures
US7137782B2 (en) * 2004-04-27 2006-11-21 General Electric Company Turbulator on the underside of a turbine blade tip turn and related method
US7207775B2 (en) * 2004-06-03 2007-04-24 General Electric Company Turbine bucket with optimized cooling circuit
US7147439B2 (en) * 2004-09-15 2006-12-12 General Electric Company Apparatus and methods for cooling turbine bucket platforms
US7163373B2 (en) * 2005-02-02 2007-01-16 Siemens Power Generation, Inc. Vortex dissipation device for a cooling system within a turbine blade of a turbine engine
US7270515B2 (en) * 2005-05-26 2007-09-18 Siemens Power Generation, Inc. Turbine airfoil trailing edge cooling system with segmented impingement ribs
US7458780B2 (en) * 2005-08-15 2008-12-02 United Technologies Corporation Hollow fan blade for gas turbine engine
US7309212B2 (en) 2005-11-21 2007-12-18 General Electric Company Gas turbine bucket with cooled platform leading edge and method of cooling platform leading edge
US7300242B2 (en) * 2005-12-02 2007-11-27 Siemens Power Generation, Inc. Turbine airfoil with integral cooling system
US7993105B2 (en) * 2005-12-06 2011-08-09 United Technologies Corporation Hollow fan blade for gas turbine engine
US7416391B2 (en) * 2006-02-24 2008-08-26 General Electric Company Bucket platform cooling circuit and method
US7488156B2 (en) * 2006-06-06 2009-02-10 Siemens Energy, Inc. Turbine airfoil with floating wall mechanism and multi-metering diffusion technique
US7549843B2 (en) * 2006-08-24 2009-06-23 Siemens Energy, Inc. Turbine airfoil cooling system with axial flowing serpentine cooling chambers
US8757974B2 (en) * 2007-01-11 2014-06-24 United Technologies Corporation Cooling circuit flow path for a turbine section airfoil
US7722326B2 (en) * 2007-03-13 2010-05-25 Siemens Energy, Inc. Intensively cooled trailing edge of thin airfoils for turbine engines
EP2265800B1 (en) * 2008-03-31 2017-11-01 Ansaldo Energia IP UK Limited Cooling duct arrangement within a hollow-cast casting
US8177507B2 (en) * 2008-05-14 2012-05-15 United Technologies Corporation Triangular serpentine cooling channels
US8167558B2 (en) * 2009-01-19 2012-05-01 Siemens Energy, Inc. Modular serpentine cooling systems for turbine engine components
GB0915680D0 (en) * 2009-09-09 2009-10-07 Rolls Royce Plc Cooled aerofoil blade or vane
US8523524B2 (en) * 2010-03-25 2013-09-03 General Electric Company Airfoil cooling hole flag region
US8905715B2 (en) 2011-03-17 2014-12-09 General Electric Company Damper and seal pin arrangement for a turbine blade
US9447691B2 (en) * 2011-08-22 2016-09-20 General Electric Company Bucket assembly treating apparatus and method for treating bucket assembly
US8807925B2 (en) 2011-09-23 2014-08-19 United Technologies Corporation Fan blade having internal rib break-edge
US9297277B2 (en) 2011-09-30 2016-03-29 General Electric Company Power plant
US10215027B2 (en) 2012-01-04 2019-02-26 United Technologies Corporation Aluminum fan blade construction with welded cover
US9221120B2 (en) 2012-01-04 2015-12-29 United Technologies Corporation Aluminum fan blade construction with welded cover
EP2692991A1 (en) * 2012-08-01 2014-02-05 Siemens Aktiengesellschaft Cooling of turbine blades or vanes
US20140069108A1 (en) * 2012-09-07 2014-03-13 General Electric Company Bucket assembly for turbomachine
US9234428B2 (en) * 2012-09-13 2016-01-12 General Electric Company Turbine bucket internal core profile
US9464536B2 (en) 2012-10-18 2016-10-11 General Electric Company Sealing arrangement for a turbine system and method of sealing between two turbine components
WO2014159800A1 (en) * 2013-03-14 2014-10-02 United Technologies Corporation Obtuse angle chevron trip strip
EP2832956A1 (en) * 2013-07-29 2015-02-04 Siemens Aktiengesellschaft Turbine blade with airfoil-shaped cooling bodies
EP2853689A1 (en) * 2013-09-25 2015-04-01 Siemens Aktiengesellschaft Arrangement of cooling channels in a turbine blade
US9551226B2 (en) 2013-10-23 2017-01-24 General Electric Company Turbine bucket with endwall contour and airfoil profile
US9670784B2 (en) 2013-10-23 2017-06-06 General Electric Company Turbine bucket base having serpentine cooling passage with leading edge cooling
US9638041B2 (en) 2013-10-23 2017-05-02 General Electric Company Turbine bucket having non-axisymmetric base contour
US9528379B2 (en) 2013-10-23 2016-12-27 General Electric Company Turbine bucket having serpentine core
US9797258B2 (en) * 2013-10-23 2017-10-24 General Electric Company Turbine bucket including cooling passage with turn
FR3020402B1 (en) * 2014-04-24 2019-06-14 Safran Aircraft Engines DRAWER FOR TURBOMACHINE TURBINE COMPRISING AN IMPROVED HOMOGENEITY COOLING CIRCUIT
US10156157B2 (en) * 2015-02-13 2018-12-18 United Technologies Corporation S-shaped trip strips in internally cooled components
EP3059394B1 (en) * 2015-02-18 2019-10-30 Ansaldo Energia Switzerland AG Turbine blade and set of turbine blades
DE102015203175A1 (en) * 2015-02-23 2016-08-25 Siemens Aktiengesellschaft Guide or blade device and casting core
WO2016135779A1 (en) * 2015-02-26 2016-09-01 株式会社 東芝 Turbine rotor blade and turbine
US10107108B2 (en) 2015-04-29 2018-10-23 General Electric Company Rotor blade having a flared tip
US20170175543A1 (en) * 2015-12-21 2017-06-22 General Electric Company Cooling circuit for a multi-wall blade
US10119406B2 (en) * 2016-05-12 2018-11-06 General Electric Company Blade with stress-reducing bulbous projection at turn opening of coolant passages
US10598028B2 (en) 2016-10-26 2020-03-24 General Electric Company Edge coupon including cooling circuit for airfoil
US10309227B2 (en) 2016-10-26 2019-06-04 General Electric Company Multi-turn cooling circuits for turbine blades
US10352176B2 (en) * 2016-10-26 2019-07-16 General Electric Company Cooling circuits for a multi-wall blade
US10301946B2 (en) 2016-10-26 2019-05-28 General Electric Company Partially wrapped trailing edge cooling circuits with pressure side impingements
US10450950B2 (en) 2016-10-26 2019-10-22 General Electric Company Turbomachine blade with trailing edge cooling circuit
US10233761B2 (en) 2016-10-26 2019-03-19 General Electric Company Turbine airfoil trailing edge coolant passage created by cover
US10465521B2 (en) 2016-10-26 2019-11-05 General Electric Company Turbine airfoil coolant passage created in cover
US10450875B2 (en) 2016-10-26 2019-10-22 General Electric Company Varying geometries for cooling circuits of turbine blades
US10273810B2 (en) 2016-10-26 2019-04-30 General Electric Company Partially wrapped trailing edge cooling circuit with pressure side serpentine cavities
US10830060B2 (en) * 2016-12-02 2020-11-10 General Electric Company Engine component with flow enhancer
KR101906701B1 (en) * 2017-01-03 2018-10-10 두산중공업 주식회사 Gas turbine blade
US10519781B2 (en) 2017-01-12 2019-12-31 United Technologies Corporation Airfoil turn caps in gas turbine engines
US10428660B2 (en) * 2017-01-31 2019-10-01 United Technologies Corporation Hybrid airfoil cooling
US10465528B2 (en) * 2017-02-07 2019-11-05 United Technologies Corporation Airfoil turn caps in gas turbine engines
US10480329B2 (en) 2017-04-25 2019-11-19 United Technologies Corporation Airfoil turn caps in gas turbine engines
US10267163B2 (en) 2017-05-02 2019-04-23 United Technologies Corporation Airfoil turn caps in gas turbine engines
US10830049B2 (en) * 2017-05-02 2020-11-10 Raytheon Technologies Corporation Leading edge hybrid cavities and cores for airfoils of gas turbine engine
EP3421721A1 (en) * 2017-06-28 2019-01-02 Siemens Aktiengesellschaft A turbomachine component and method of manufacturing a turbomachine component
CN111247313B (en) * 2017-08-24 2023-01-31 西门子能源全球两合公司 Turbine rotor airfoil and corresponding method for reducing pressure loss in cavity within blade
US10767509B2 (en) * 2017-10-03 2020-09-08 Raytheon Technologies Corporation Trip strip and film cooling hole for gas turbine engine component
US10830059B2 (en) * 2017-12-13 2020-11-10 Solar Turbines Incorporated Turbine blade cooling system with tip flag transition
US10731475B2 (en) * 2018-04-20 2020-08-04 Raytheon Technologies Corporation Blade with inlet orifice on aft face of root
US11220914B1 (en) * 2020-09-23 2022-01-11 General Electric Company Cast component including passage having surface anti-freckling element in turn portion thereof, and related removable core and method
CN113586166B (en) * 2021-07-20 2022-09-16 西安交通大学 Turbine blade with kerosene cooling micro-channel
US11814965B2 (en) 2021-11-10 2023-11-14 General Electric Company Turbomachine blade trailing edge cooling circuit with turn passage having set of obstructions

Family Cites Families (49)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CA545792A (en) * 1957-09-03 A. Lombard Adrian Bladed stator or rotor constructions for fluid machines
US2469678A (en) * 1943-12-18 1949-05-10 Edwin T Wyman Combination steam and gas turbine
US2787121A (en) * 1946-01-28 1957-04-02 Bouffart Maurice Arrangement for cooling combustion chambers and compressors of a stationary power plant with water or steam from a boiler
US2647368A (en) * 1949-05-09 1953-08-04 Hermann Oestrich Method and apparatus for internally cooling gas turbine blades with air, fuel, and water
NL88170C (en) * 1952-10-31 1900-01-01
GB774499A (en) * 1953-06-19 1957-05-08 Power Jets Res & Dev Ltd Corrugated-cored elements for use in turbines, compressors and combustion equipment
GB806033A (en) * 1955-09-26 1958-12-17 Rolls Royce Improvements in or relating to fluid machines having bladed rotors
GB904546A (en) * 1958-03-17 1962-08-29 Rolls Royce Improvements in or relating to rotor blades of turbines and compressors
GB856674A (en) * 1958-06-18 1960-12-21 Rolls Royce Blades for gas turbine engines
GB861632A (en) * 1958-06-25 1961-02-22 Rolls Royce Method and apparatus for cooling a member such, for example, as a turbine blade of agas turbine engine
GB880069A (en) * 1958-08-28 1961-10-18 Rolls Royce Improvements in or relating to turbine or like blades and rotors incorporating such blades
US3275294A (en) * 1963-11-14 1966-09-27 Westinghouse Electric Corp Elastic fluid apparatus
US3443790A (en) * 1966-07-08 1969-05-13 Gen Electric Steam cooled gas turbine
US3729930A (en) * 1970-06-23 1973-05-01 Rolls Royce Gas turbine engine
US3749514A (en) * 1971-09-30 1973-07-31 United Aircraft Corp Blade attachment
BE794195A (en) * 1972-01-18 1973-07-18 Bbc Sulzer Turbomaschinen COOLED STEERING VANE FOR GAS TURBINES
US3785146A (en) * 1972-05-01 1974-01-15 Gen Electric Self compensating flow divider for a gas turbine steam injection system
US4073599A (en) * 1976-08-26 1978-02-14 Westinghouse Electric Corporation Hollow turbine blade tip closure
US4136516A (en) * 1977-06-03 1979-01-30 General Electric Company Gas turbine with secondary cooling means
JPS5477820A (en) * 1977-12-02 1979-06-21 Hitachi Ltd Method of cooling gas turbine blade
US4545197A (en) * 1978-10-26 1985-10-08 Rice Ivan G Process for directing a combustion gas stream onto rotatable blades of a gas turbine
US4438625A (en) * 1978-10-26 1984-03-27 Rice Ivan G Reheat gas turbine combined with steam turbine
US4314442A (en) * 1978-10-26 1982-02-09 Rice Ivan G Steam-cooled blading with steam thermal barrier for reheat gas turbine combined with steam turbine
US4384452A (en) * 1978-10-26 1983-05-24 Rice Ivan G Steam-cooled blading with steam thermal barrier for reheat gas turbine combined with steam turbine
US4835958A (en) * 1978-10-26 1989-06-06 Rice Ivan G Process for directing a combustion gas stream onto rotatable blades of a gas turbine
US4571935A (en) * 1978-10-26 1986-02-25 Rice Ivan G Process for steam cooling a power turbine
GB2041100B (en) * 1979-02-01 1982-11-03 Rolls Royce Cooled rotor blade for gas turbine engine
EP0062932B1 (en) * 1981-04-03 1984-12-05 BBC Aktiengesellschaft Brown, Boveri & Cie. Combined steam and gas turbine power plant
US4550562A (en) * 1981-06-17 1985-11-05 Rice Ivan G Method of steam cooling a gas generator
GB2100807B (en) * 1981-06-30 1984-08-01 Rolls Royce Turbine blade for gas turbine engines
JPS59126034A (en) * 1983-01-10 1984-07-20 Hitachi Ltd Cooling system for gas turbine
FR2540937B1 (en) * 1983-02-10 1987-05-22 Snecma RING FOR A TURBINE ROTOR OF A TURBOMACHINE
US4807433A (en) * 1983-05-05 1989-02-28 General Electric Company Turbine cooling air modulation
JPS60135604A (en) * 1983-12-22 1985-07-19 Toshiba Corp Gas turbine cooling blade
JPS60206905A (en) * 1984-03-31 1985-10-18 Toshiba Corp Re-heating steam turbine warm-up device
US5232343A (en) * 1984-05-24 1993-08-03 General Electric Company Turbine blade
US5177954A (en) * 1984-10-10 1993-01-12 Paul Marius A Gas turbine engine with cooled turbine blades
US4969324A (en) * 1988-07-13 1990-11-13 Gas Research Institute Control method for use with steam injected gas turbine
US4982564A (en) * 1988-12-14 1991-01-08 General Electric Company Turbine engine with air and steam cooling
JP3142850B2 (en) * 1989-03-13 2001-03-07 株式会社東芝 Turbine cooling blades and combined power plants
IT1243682B (en) * 1989-07-28 1994-06-21 Gen Electric GAS TURBO ENGINE STEAM COOLING
JPH03194101A (en) * 1989-12-21 1991-08-23 Toshiba Corp Gas turbine cooling moving blade
US5165852A (en) * 1990-12-18 1992-11-24 General Electric Company Rotation enhanced rotor blade cooling using a double row of coolant passageways
US5156526A (en) * 1990-12-18 1992-10-20 General Electric Company Rotation enhanced rotor blade cooling using a single row of coolant passageways
US5160096A (en) * 1991-10-11 1992-11-03 United Technologies Corporation Gas turbine cycle
US5413463A (en) * 1991-12-30 1995-05-09 General Electric Company Turbulated cooling passages in gas turbine buckets
US5350277A (en) * 1992-11-20 1994-09-27 General Electric Company Closed-circuit steam-cooled bucket with integrally cooled shroud for gas turbines and methods of steam-cooling the buckets and shrouds
US5403159A (en) * 1992-11-30 1995-04-04 United Technoligies Corporation Coolable airfoil structure
US5391052A (en) * 1993-11-16 1995-02-21 General Electric Co. Impingement cooling and cooling medium retrieval system for turbine shrouds and methods of operation

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US9726024B2 (en) 2011-12-29 2017-08-08 General Electric Company Airfoil cooling circuit
US9638051B2 (en) 2013-09-04 2017-05-02 General Electric Company Turbomachine bucket having angel wing for differently sized discouragers and related methods

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IN186935B (en) 2001-12-15
EP0735240A1 (en) 1996-10-02
KR960034690A (en) 1996-10-24
US5536143A (en) 1996-07-16
JP3894974B2 (en) 2007-03-22
JPH08319803A (en) 1996-12-03
KR100393725B1 (en) 2003-11-03
DE69612319T2 (en) 2002-05-02
DE69612319D1 (en) 2001-05-10

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